TY - JOUR
T1 - The effects of ionizing radiation on the structure and antioxidative and metal binding capacity of the cell wall of microalga Chlorella sorokiniana
AU - Vojvodić, Snežana
AU - Danilović Luković, Jelena
AU - Zechmann, Bernd
AU - Jevtović , Mima
AU - Bogdanović Pristov , Jelena
AU - Stanić, Marina
AU - Lizzul, Alessandro Marco
AU - Pittman, Jon
AU - Spasojević, Ivan
PY - 2020/7/8
Y1 - 2020/7/8
N2 - The impact of ionizing radiation on microorganisms such as microalgae is a topic of increasing importance for understanding the dynamics of aquatic ecosystems in response to environmental radiation, and for the development of efficient approaches for bioremediation of mining and nuclear power plants wastewaters. Currently, nothing is known about the effects of ionizing radiation on the microalgal cell wall, which represents the first line of defence against chemical and physical environmental stresses. Using various microscopy, spectroscopy and biochemical techniques we show that the unicellular alga Chlorella sorokiniana elicits a fast response to ionizing radiation. Within one day after irradiation with doses of 1–5 Gy, the fibrilar layer of the cell wall became thicker, the fraction of uronic acids was higher, and the capacity to remove the main reactive product of water radiolysis increased. In addition, the isolated cell wall fraction showed significant binding capacity for Cu
2+, Mn
2+, and Cr
3+. The irradiation further increased the binding capacity for Cu
2+, which appears to be mainly bound to glucosamine moieties within a chitosan-like polymer in the outer rigid layer of the wall. These results imply that the cell wall represents a dynamic structure that is involved in the protective response of microalgae to ionizing radiation. It appears that microalgae may exhibit a significant control of metal mobility in aquatic ecosystems via biosorption by the cell wall matrix.
AB - The impact of ionizing radiation on microorganisms such as microalgae is a topic of increasing importance for understanding the dynamics of aquatic ecosystems in response to environmental radiation, and for the development of efficient approaches for bioremediation of mining and nuclear power plants wastewaters. Currently, nothing is known about the effects of ionizing radiation on the microalgal cell wall, which represents the first line of defence against chemical and physical environmental stresses. Using various microscopy, spectroscopy and biochemical techniques we show that the unicellular alga Chlorella sorokiniana elicits a fast response to ionizing radiation. Within one day after irradiation with doses of 1–5 Gy, the fibrilar layer of the cell wall became thicker, the fraction of uronic acids was higher, and the capacity to remove the main reactive product of water radiolysis increased. In addition, the isolated cell wall fraction showed significant binding capacity for Cu
2+, Mn
2+, and Cr
3+. The irradiation further increased the binding capacity for Cu
2+, which appears to be mainly bound to glucosamine moieties within a chitosan-like polymer in the outer rigid layer of the wall. These results imply that the cell wall represents a dynamic structure that is involved in the protective response of microalgae to ionizing radiation. It appears that microalgae may exhibit a significant control of metal mobility in aquatic ecosystems via biosorption by the cell wall matrix.
KW - Alga
KW - Cell wall
KW - Copper
KW - Radiation
U2 - 10.1016/j.chemosphere.2020.127553
DO - 10.1016/j.chemosphere.2020.127553
M3 - Article
SN - 0045-6535
VL - 260
JO - Chemosphere
JF - Chemosphere
M1 - 127553
ER -